Method and system for wireless power delivery

ABSTRACT

A system for wireless power delivery including one or more transmitters and receivers. A method for wireless power delivery, preferably including: determining transmitter-receiver proximity; determining transmission parameter values, preferably including determining initial parameter values, evaluating candidate transmission parameter values, performing one or more local optimum searches, and/or performing one or more global optimum searches; and transmitting power based on the transmission parameter values.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/001,725, filed on 6 Jun. 2018, which claims the benefit of U.S.Provisional Application Ser. No. 62/515,962, filed on 6 Jun. 2017, andU.S. Provisional Application Ser. No. 62/516,572, filed on 7 Jun. 2017,each of which is incorporated in its entirety by this reference.

TECHNICAL FIELD

This invention relates generally to the wireless power delivery field,and more specifically to a new and useful method and system in thewireless power delivery field.

BACKGROUND

Typical wireless power delivery systems restrict themselves tobeamforming configurations, which may not offer high-performanceresults. Thus, there is a need in the wireless power delivery field tocreate a new and useful method and system for wireless power delivery.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1A is a schematic representation of a first embodiment of thesystem.

FIGS. 1B-1C are schematic representations of an example of a transmitterand receiver, respectively, of the system.

FIG. 1D is a schematic representation of a second embodiment of thesystem.

FIGS. 2A-2B are schematic representations of the method and an exampleof an element of the method.

FIG. 3 is a representation of an example of an objective function and amodified version of the objective function.

FIG. 4A is a perspective view of an example of an antenna.

FIG. 4B is a plan view of a cross resonator of the example of theantenna.

FIG. 4C is a perspective view of an example of a split-ring resonator.

FIGS. 5A-5D are plan views of specific examples of anelectro-inductive-capacitive resonator.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The following description of the preferred embodiments of the inventionis not intended to limit the invention to these preferred embodiments,but rather to enable any person skilled in the art to make and use thisinvention.

1. Overview.

A system for wireless power delivery can include one or moretransmitters and receivers (e.g., as shown in FIGS. 1A-1D). A method forwireless power delivery can include determining transmitter-receiverproximity S100, determining transmission parameter values S200, andtransmitting power based on the transmission parameter values S300(e.g., as shown in FIG. 2A). However, the system and method canadditionally or alternatively include any other suitable elements. Themethod is preferably performed using the system described above, but canadditionally or alternatively be performed using any other suitablesystem.

Determining power transmission settings for efficient wireless powerdelivery using typical methods and systems can be difficult and/ortime-intensive. Assessment of candidate power transmission settings canbe a slow process (e.g., requiring 1-100 ms or more). In addition, thepower transmission settings typically involve a large number ofparameters, and so the search space can be very large, effectivelyprecluding its full exploration. Further, the elements of the system andthe surrounding element may move frequently, potentially invalidatingprior solutions and necessitating a new search. In light of theseproblems, the inventors have discovered that a rapidly-determinedsolution (e.g., a solution resulting in power transmission within athreshold range of a limit or optimal result) can be superior to aglobally-optimal solution found only after a lengthy search.

2. Benefits.

The method can significantly reduce the time needed to determineacceptable and/or desirable power transmission settings. First, themethod can include performing a local search or stochastic globalsearch, which can typically find a sufficient solution in much less timethan a deterministic global search. This search time reduction willoften produce vastly superior energy transmission results (e.g., in asystem with changing element orientations).

Second, evaluation of power transmission settings (e.g., during thelocal and/or global searches) can be time-consuming, such as due to theneed to configure the transmitter according to the settings, measure(e.g., at the receiver) the result of power transmission using thesettings, and/or communicate the results between different entities(e.g., transmit results from the receiver to the transmitter). To reducesuch time consumption, the method can optionally include estimatingand/or caching the evaluations and/or associated information, therebyallowing fast lookup of the estimated and/or cached values in place offull evaluation.

Third, employing power transmission optimization techniques (e.g.,real-time optimization techniques, such as optimization overtransmission parameters based on measured results associated with theparameters) can enable excitation and/or maintenance of supergainingbehavior in receiver and/or transmitter antennas, despite potentialchanges in environment and/or system configuration. Further, use ofpure-tone (and/or substantially pure-tone) signals for powertransmission can make use of such supergaining antennas feasible,despite the narrow bandwidths (e.g., fractional impedance bandwidths)typically associated with such antennas (e.g., arising from thehigh-energy evanescent fields typically generated in and/or around suchantennas). Supergaining antennas can exhibit much higher gain thantypical antennas, thereby enabling, for example, increased powertransmission rates and/or decreased receiver and/or transmitter sizes.However, the method and system can additionally or alternatively conferany other suitable benefits.

3. System.

The transmitters of the system can include one or more antennas (e.g.,configured to transmit electromagnetic radiation, such as RF and/ormicrowave power), preferably defining a controllable (e.g., adaptive)antenna array (e.g., linear array, planar array, 3-D array, etc.; phasedarray, electronically controllable array, etc.).

The antenna array preferably includes a plurality of active antennas(e.g., antennas configured to be actively driven by feeds), morepreferably independently controllable active antennas (e.g., whereineach active antenna can be individually controlled independent of allother active antennas of the system; wherein groups of active antennascan be controlled together, wherein each group is controllableindependently from all other groups; etc.). In a first variation, theamplitude and/or phase at which each active antenna is driven can beindependently controlled (e.g., via a separate IQ modulator or phaseshifter for each active antenna). In a second variation, the activeantennas are separated into one or more antenna groups, wherein theantennas of a group are controlled together (e.g., via a single IQmodulator or phase shifter for each group). For example, the antennas ofa group can have a fixed phase offset (e.g., zero offset, such aswherein all antenna of the group have the same phase as each other;non-zero offset; etc.) with respect to each other (e.g., wherein thefixed phase offset is defined by differences in trace lengths betweenthe IQ modulator or phase shifter and each antenna). However, the activeantennas can additionally or alternatively be configured in any othersuitable manner.

The antenna array can additionally or alternatively include one or morepassive antennas (e.g., configured to electrically and/or resonantlycouple to one or more of the active antennas, thereby altering antennaarray transmission characteristics). In one example, the system isconfigured to control (e.g., via switches, such as software-controlledswitches; via elements with variable electrical properties, such asvariable capacitors; etc.) electrical coupling (e.g., connection,resonant coupling, etc.) and/or decoupling of one or more of the passiveantennas to one or more electrical components (e.g., passive components,such as resistors, capacitors, and/or inductors; antennas, such as oneor more of the active antennas and/or other passive antennas; etc.). Ina first example, a plurality of passive antennas can be electricallyconnected to and/or disconnected from each other (e.g., via switchesoperable to electrically connect two or more such antennas). In a secondexample, variable capacitors (e.g., varactors) and/or other variable(e.g., continuously-variable) elements are electrically coupled (e.g.,electrically connected) to one or more passive antennas, enablingcontrol of the loading of the passive antennas and/or their coupling toother antennas (e.g., other passive antennas, active antennas, etc.) inthe array and/or their feeds (e.g., wherein varying the properties ofone or more of the variable elements coupled to the antennas canfunction to control the net pattern of the array). In a specific exampleof this second example, an adaptive antenna array includes a singleactive antenna and a plurality of passive antennas, wherein one or moreof the passive antennas are electrically coupled to one or more variablecomponents. However, the transmitters can additionally or alternativelyinclude any other suitable elements.

The receivers of the system can include one or more antennas (e.g.,configured to receive electromagnetic radiation transmitted by thetransmitters). The receivers can optionally include and/or beelectrically coupled to (e.g., configured to deliver electrical powerto) one or more client devices (e.g., batteries and/orbattery-containing devices, such as smart phones and/or other electricaland/or electronic user devices). The receivers can optionally includeone or more buffer energy stores (e.g., batteries), such as a batteryelectrically coupled between the antenna(s) and the client device (e.g.,between the antenna(s) and an electrical output configured to connect tothe client device), which can function as a buffer between the antennas(which may provide power at an uneven rate and/or with unevencharacteristics) and the client device (which may require and/or benefitfrom power provision at a substantially constant rate and/or withsubstantially constant characteristics, which may be temporarilydisconnected from the receiver, etc.).

In some embodiments, some or all of the antennas of the transmitter(e.g., active antennas, passive antennas, etc.) and/or receiver includeone or more tightly-coupled arrays of resonators (e.g., as shown in FIG.4A), but can additionally or alternatively include a loosely-coupledarray, a sparse array, a single resonator, and/or any other suitableantenna elements. The resonators can include resonant loops,cross-resonators (e.g., as shown in FIG. 4B), split-ring resonators(e.g., as shown in FIG. 4C), electro-inductive-capacitive resonators(e.g., as shown in FIGS. 5A-5D), other physically small resonators(e.g., small relative to their resonance wavelength), and/or any othersuitable resonators. However, the resonators can be otherwiseconfigured.

The antenna(s) can optionally include multiple arrays (and/or otherresonator arrangements) arranged with different orientations, which canfunction to efficiently couple to radiation of different polarizations(e.g., orthogonal polarizations). In a first embodiment, an antennaincludes parallel resonator layers (e.g., parallel resonator arrays),each layer having a different in-plane resonator orientation (e.g.,orthogonal orientations, oriented at oblique angles, etc.). In a secondembodiment, an antenna includes resonators on non-parallel planes (e.g.,orthogonal planes, planes oriented at oblique angles, etc.). However,the antenna(s) can additionally or alternatively include any othersuitable resonators and/or other antenna elements, and can have anyother suitable arrangement. The antenna(s) can be a metamaterial or haveany other suitable configuration.

The antennas of the transmitter (e.g., active antennas, passiveantennas, etc.) and/or receiver can optionally include one or moresupergaining antennas, supergaining arrays, arrays of supergainingantennas, and/or any other suitable structures capable or and/orconfigured to exhibit supergaining behavior (e.g., supergain antennas asdescribed in Harrington, R. F. (1960), ‘Effect of antenna size on gain,bandwidth, and efficiency’, J. Res. Nat. Bur. Stand 64D (1), 1-12, whichis hereby incorporated in its entirety by this reference). Supergainingstructures can exhibit very high gain relative to their physical size.For example, such structures can exhibit an electrical area A_(e),defined as

${A_{e} = \frac{G\; \lambda^{2}}{4\pi}},$

wherein λ is the radiation wavelength and G is the antenna gain at thatwavelength, much greater that their physical area (e.g., footprint). Ina first example, in which the antenna(s) define a sub-wavelengthstructure (e.g., define a length scale less than the radiationwavelength), the structures can exhibit an aperture efficiency, definedas A_(e)/A, of 2-100 (e.g., 6.5-10, 10-15, 15-22, 22-35, less than 6.5,greater than 25, etc.) and a quality factor of 100-5,000,000 (e.g.,500-5000, 5000-50,000, 50,000-750,000, less than 500, greater than750,000, etc.). In a second example, in which the antenna(s) define asuper-wavelength structure (e.g., define a length scale greater than theradiation wavelength), the structures can exhibit an aperture efficiencyof 1-10 (e.g., 1.5-1.6, 1.6-1.7, 1.7-1.8, 1.8-1.9, 1.9-2, 2-2.15, lessthan 1.5, greater than 2.15, etc.) and a quality factor of 10-5,000,000(e.g., 50-500, 500-5000, 5000-50,000, 50,000-750,000, less than 500,greater than 750,000, etc.). However, the structures can additionally oralternatively define any other suitable aperture efficiencies and/orquality factors.

In a first variation, such structures can include one or more resonatorsdefining geometries that include sub-wavelength features (e.g., featuresdefining characteristic dimensions smaller than the wavelengths ofradiation that the resonator is configured to resonate withefficiently), such as cross-resonators (e.g., as shown in FIG. 4B),split-ring resonators (e.g., as shown in FIG. 4C), and/orelectro-inductive-capacitive resonators (e.g., as shown in FIGS. 5A-5D).In a second variation, such structures can include a discretizedaperture (e.g., array of metamaterial unit cells, such ascross-resonators, split-ring resonators, and/orelectro-inductive-capacitive resonators; example shown in FIG. 4A),wherein the discrete elements of the aperture are controlled (e.g.,independently, separately, etc.), such as to approximate a continuousdistribution across the aperture. In a third variation, such structurescan include an array of classical antenna elements (e.g., patchantennas, dipole antennas, etc.) arranged to enable and/or enhancesupergaining behavior (e.g., as described in M. T. Ivrlač and J. A.Nossek, “High-efficiency super-gain antenna arrays,” 2010 InternationalITG Workshop on Smart Antennas (WSA), Bremen, 2010, pp. 369-374, whichis hereby incorporated in its entirety by this reference).

The transmitters and receivers can additionally or alternatively beconfigured to transmit and/or receive energy in any other suitable form(e.g., sonic, optical, etc.), and/or to perform any other suitablerole(s). In one embodiment, all or some of the transmitters canadditionally function as receivers and/or all or some of the receiverscan additionally function as transmitters. For example, the system caninclude a plurality of equivalent devices, each of which can wirelesslytransmit power to and receive power from each of the other devices.

The transmitters and receivers preferably each include a wirelesscommunication module, but can additionally or alternatively includewired communication modules or any other suitable communication modules,or can omit communication modules. The wireless communication modulespreferably support (e.g., enable communication using) one or morewireless communication protocols (e.g., WiFi, Bluetooth, BLE, NFC, RF,IR, Zigbee, Z-wave, etc.). However, the transmitters and receivers canadditionally or alternatively include any other suitable elements.

The transmitters and receivers preferably have an arbitrary and/ordynamic arrangement with respect to each other. In one example, thesystem includes a transmitter with a fixed position, and a plurality ofreceivers, each of which undergo numerous changes in position andorientation (e.g., with respect to the transmitter, each other, etc.)over time. The system can optionally be arranged in a setting in whichother nearby objects (e.g., obstacles to wireless power transmission)can also have an arbitrary and/or dynamic arrangement with respect tothe elements of the system. However, the system can define any othersuitable arrangements.

4. Method. 4.1 Determining Transmitter-Receiver Proximity.

Determining transmitter-receiver proximity S100 can function to indicatean opportunity for wireless power delivery (e.g., from the transmitterto the receiver). For example, S100 can include determining that one ormore receivers are in transmission range (e.g., a range enablingefficient power transmission, substantial power transmission, anymeasurable power transmission, etc.) of the transmitter.Transmitter-receiver proximity is preferably determined using wirelesscommunication (e.g., using the wireless communication modules of thetransmitter and receiver). For example, one device can determine thatthe other is nearby based on establishment of wireless communicationbetween them, wireless communication signal strength (e.g., RSSI),information communicated via wireless connection, and/or any othersuitable indications.

Determining transmitter-receiver proximity S100 can additionally oralternatively include optical recognition (e.g., detecting a nearbyreceiver in an image captured by a camera of a transmitter), receiving auser input (e.g., button press), detecting a change in wireless powerdelivery, and/or any other suitable elements. For example, a transmitterwirelessly transmitting power to a first receiver can detect the arrivalof a second receiver based on a reduction in power delivered to thefirst receiver.

S100 can additionally or alternatively include determining informationabout the receiver and/or transmitter. The information can includedevice type (e.g., model, serial number, etc.), power needs (e.g.,battery charge state, current power draw, etc.), likely (e.g., typical,planned, predicted, etc.) residence time in proximity, likely positionstability while in proximity (e.g., stationary on table, moving in userclothing pocket, etc.), device position (e.g., based ontrilateration/triangulation, optical recognition, line-of-sightproximity sensor, device IMU readings, device GPS readings, etc.),and/or any other suitable information. However, S100 can additionally oralternatively include any other suitable elements.

4.2 Determining Transmission Parameter Values.

Determining transmission parameter values S200 can function to searchfor transmission parameter values that can enable efficient powertransmission (e.g., from the transmitters to the receivers).Transmission parameter values are preferably determined S200 in responseto determining transmitter-receiver proximity S100, but can additionallyor alternatively be performed at any other suitable time. Thetransmission parameters can include: transmission phase (e.g., relativeto a reference phase, such as a transmission phase of a referenceantenna) and/or transmission amplitude of one or more antennas,beamforming parameters such as beam orientation (e.g., angles describingthe beam orientation, such as azimuthal angle and polar angle),supergaining excitation parameters such as supergaining receiver type,position, and/or orientation, passive antenna parameters such asresistance, capacitance, and/or inductance coupled to one or moreantennas (e.g., electrical component coupling parameters), and/or anyother suitable parameters. In a first example, the transmissionparameters include transmission phase and/or amplitude for one or moreactive antennas and/or antenna groups (e.g., hardware-defined groups,software-defined groups, etc.), preferably for each active antenna ofthe transmitter (e.g., of the antenna array, such as the phased antennaarray or other adaptive antenna array) or transmitters. In a secondexample, the transmission parameters include beamforming parametersassociated with one or more beamforming networks (e.g., Rotman lens,Butler matrix, etc.) defined by the antennas (e.g., wherein one or moreantenna groups, such as software-defined antenna groups, each define aseparate beamforming network). In a third example, the transmissionparameters include supergaining excitation parameters associated withone or more supergaining structures (e.g., antennas, arrays, etc.)defined by the antennas of the transmitter (e.g., wherein one or moreantenna groups, such as hardware- and/or software-defined antennagroups, each define a separate supergaining structures) and/or receiver.However, the transmission parameters can additionally or alternativelyinclude any other suitable parameters.

Determining transmission parameter values S200 can optionally includedetermining one or more antenna groups (e.g., software-defined antennagroups), which can be used to reduce the dimension of the transmissionparameter space (e.g., a space defined by the transmission parameters,distinct from a physical space defined by object positions and/ororientations within a spatial region such as a room). For example,rather than independently controlling parameters (e.g., transmissionphase and/or amplitude) associated with each active antenna, thedimension of the transmission parameter space can be reduced toparameters associated with each antenna group (e.g., transmission phaseand/or amplitude, beamforming parameters, supergaining excitationparameters, etc.). In a first embodiment, the groups are predefined(e.g., based on properties of the transmitter; based on properties offixed elements near the transmitter, such as for a transmitter installedin a fixed position; etc.). In a second embodiment, the groups aredynamically determined, such as based on statistical analysis and/ormachine learning techniques (e.g., using data determined as describedbelow, such as data associated with wireless power received at one ormore receivers of the system). For example, principal component analysisand/or clustering techniques (e.g., k-means clustering, X-meansclustering, spectral clustering, etc.) can be employed to determine theantenna groups (e.g., wherein highly correlated antennas and/or antennaparameters are grouped together, wherein antennas of a cluster aregrouped together, etc.). However, the antenna groups can additionally oralternatively be determined in any other suitable manner, or no antennagroups can be determined.

Determining transmission parameter values S200 preferably includesperforming one or more optimum searches (e.g., as described belowregarding the local and global optimum searches). The objective functionfor the optimum searches is preferably based on the power and/or energydelivered to the receiver(s), but can additionally or alternatively bebased on any other suitable variables. For example, the objectivefunction can be equal to the received power, which can optionally benormalized, such as by the transmitter power (e.g., and thereby equal tothe power transmission efficiency). The received power can be determined(e.g., measured) at the receiver antenna, at the client device (and/or apower output configured to deliver power to a client device), at thebuffer energy store, and/or at any other suitable portion of thereceiver (e.g., between the antenna and the buffer energy store; betweenthe buffer energy store and the client device or power output; betweenthe antenna and the client device or power output, such as inembodiments with no buffer energy store; etc.). In one example, in whichthe receiver includes one or more dynamic impedance matches (e.g.,configured to optimize power coupling from the receiver antenna(s)), thereceiver continuously optimizes the dynamic impedance match(es), andtransmits data representing the optimized power magnitude measured near(e.g., at the output of) the dynamic impedance match(es), such asdescribed in U.S. Application 62/515,962, titled “System for WirelessPower Reception”, and/or U.S. application Ser. No. 16/001,628, titled“System and Method for Wireless Power Reception”, each of which ishereby incorporated in its entirety by this reference (e.g., asdescribed regarding the dynamic impedance match, such as regarding thetuning network, power measurement module, and/or control network).Additionally or alternatively, the received power can be measuredexternal the receiver (e.g., at a system element other than thereceiver).

In embodiments in which the transmitter(s) transmit to multiplereceivers (e.g., first receiver, second receiver, third receiver, fourthreceiver, etc.), the objective function is preferably a multivariablefunction of the power received at each receiver (and can optionally be avector-valued function, such as for use in multi-objectiveoptimization). In one embodiment, the objective function for a set of nreceivers is equal to:

${\sum\limits_{i = 1}^{n}\; {w_{i}f_{i}}} + {P_{i}\left( {{f_{i} - f_{i}^{*}}} \right)}$

wherein ƒ_(i) is an objective function value associated with receiver i,ƒ_(i)* is an optimal (e.g., observed, estimated, etc.) value of ƒ_(i)(e.g., the value of ƒ_(i) under transmission parameters for which ƒ_(i)is optimized), w_(i) is a weight associated with receiver i, and P_(i)is a penalty function associated with receiver i. The weights and/orpenalty functions can be equivalent and/or different for the differentreceivers. In a first example, performance associated with one or morereceivers is ignored (or partially ignored) by setting the associatedweights and/or penalty functions to zero. In a second example, theperformance associated with one or more receivers is ignored only iftheir associated objective functions remain within a threshold distanceT_(i) of the ideal value (e.g., a fractional amount of ƒ_(i)*, such as1%, 2%, 5%, 10%, 15%, 20%, 25%, 50%, 75%, 90%, 95%, 0-5%, 5-15%, 15-45%,45-75%, 75-95%, 95-100%, etc.), wherein the associated weights are setequal to zero and the associated penalty functions are zero forarguments less than T_(i) and infinite for arguments greater than orequal to T_(i). In a third example, the objective function can be a sumor average of the received power at each receiver (e.g., w_(i)=1 orw_(i)=1/n and P_(i)=0 for all i).

In additional examples, the objective function can be optimized by adesired distribution of power delivery to each of the receivers (e.g.,evenly-distributed, exceeding a minimum threshold for each receiver, aPareto front distribution, etc.), can be determined based on receiverinformation (e.g., battery charge states, expected power needs, etc.),and/or can be determined based on any other suitable criteria. Thesearches can seek to maximize or minimize the objective function. Eachsearch (and/or iteration of a search) can use the same objectivefunction or different objective functions.

The objective function (e.g., for a multi-receiver system) canoptionally be determined based on receiver prioritization. The receiverprioritization can include receiver priority scores, rankings,classifications (e.g., high, medium, low, ignore, etc.), and/or anyother suitable prioritizations. The receiver prioritizations can beused, for example, to determine the weights and/or penalty functions ofthe objective function (e.g., wherein a higher-priority receivercorresponds to a higher weight than a lower-priority receiver). Theprioritizations can be determined based on: expected receiver residencetime (e.g., wherein a very short time corresponds to a “low” or “ignore”priority, a short time corresponds to a “moderate” priority, anintermediate time corresponds to a “high” priority, and a long time,such as a time far in excess of the time needed to substantially fullycharge the receiver's battery, corresponds to a “low” or “intermediate”priority, etc.), expected time required to charge receiver battery(e.g., wherein a longer expected charging time corresponds to a higherprioritization), receiver battery state (e.g., wherein a very lowbattery state, such as a state in which an electronic device powered bythe battery may soon power off, cease to function, and/or enter astandby mode, corresponds to a higher prioritization), user preferences,and/or any other suitable information.

Determining transmission parameter values S200 can include determininginitial parameter values S210, evaluating candidate transmissionparameter values S220, performing a local optimum search S230, and/orperforming a global optimum search S240 (e.g., as shown in FIG. 2B).However, S200 can additionally or alternatively include any othersuitable elements.

4.2.1 Determining Initial Parameter Values.

Determining initial parameter values S210 can function to provide aninitial guess and/or a starting point for the optimum search.

In a first embodiment, the initial parameter values can be predeterminedand/or fixed (e.g., hardcoded). For example, the initial parametervalues can correspond to beam-like patterns (e.g., most radio powerdirected within a narrow cone, such as a cone with a 5° aperture, arounda beam, such as a beam directed normal to the antenna array, parallel anedge of the antenna array, etc.), multi-beam patterns (e.g., severalbeam-like patterns propagating in different directions), wide patterns(e.g., significant radio power spread over a wide distribution ofangles, such as over a cone with a 90° aperture), omni-directionalpatterns (e.g., radiating power in a pattern with substantiallycylindrical symmetry, such as radiating substantially equal power in allazimuthal directions perpendicular to an axis, such as an array normalaxis), supergaining excitation patterns (e.g., configured to excitesupergaining behavior in one or more supergaining structures of thereceiver(s) and/or transmitter(s), such as precomputed patterns based onknown and/or assumed supergaining structure types, positions, and/ororientations; such as described in M. T. Ivrlač and J. A. Nossek,“High-efficiency super-gain antenna arrays,” 2010 International ITGWorkshop on Smart Antennas (WSA), Bremen, 2010, pp. 369-374, which ishereby incorporated in its entirety by this reference), and/or any othersuitable radiation patterns. The initial parameter values canadditionally or alternatively include randomly-selected values (e.g.,modifying the predetermined and/or fixed values).

In a second embodiment, the initial parameter values can be can bedetermined based on historical data (e.g., can be equal to transmissionparameter values determined in a previous performance of the method).The historical data can include data associated with the transmitter,the receiver, and/or any other transmitters, receivers, or otherdevices. The initial parameter values can additionally or alternativelyinclude randomly-selected values (e.g., modifying the values determinedbased on historical data). In a first example of this embodiment, theinitial parameter values are set equal to the most recent optimizedtransmission parameter values determined by the system. In a secondexample, the initial parameter values are set equal to the most recentoptimized transmission parameter values determined by a fast search(e.g., determined by a local optimum search, wherein a global search wasdetermined to be unnecessary). In a third example, the initial parametervalues are set equal to the most recent optimized transmission parametervalues corresponding to a beam-like radiation pattern. In a fourthexample, the initial parameter values are set equal to optimizedtransmission parameter values associated with a similar arrangement(e.g., determined based on the receiver position and/or orientation,such as by an IMU). In a fifth example, the initial parameter values aredetermined based on the historical data using machine learningtechniques (e.g., cluster algorithms, function estimation, multi-layerneural networks, etc.), such as to predict usage patterns. However, theinitial parameter values can be determined based on any other suitablehistorical data, and/or can be determined in any other suitable manner(e.g., determined randomly).

4.2.2 Evaluating Candidate Transmission Parameter Values.

Evaluating candidate transmission parameter values S220 can function todetermine the objective function value associated with the candidatetransmission parameter values. Evaluating candidate values S220 caninclude transmitting based on the candidate values S221, measuringresults of the transmission S222, and/or evaluating the objectivefunction based on the measurement S223. S220 can additionally oralternatively include estimating the objective function value (e.g.,based on historical data, by evaluating a proxy function, etc.).Evaluating candidate transmission parameter values S220 can be performedperiodically, performed upon evaluation trigger event occurrence (e.g.,detecting object movement within the power transmission region), and/orat any other suitable time.

Transmitting S221 preferably includes controlling one or more antennasof the transmitter antenna array (e.g., adaptive antenna array, such asa phased antenna array). Preferably, each antenna of the array iscontrolled independently, but some or all of the antennas canalternatively be controlled jointly, controlled in groups (e.g.,hardware-defined groups and/or software-defined groups, such asdescribed above, etc.), controlled in any other suitable manner, and/orcan be not controlled. The tested antenna parameter values (e.g.,parameter value set) can be the initial parameter values, bepredetermined (e.g., a predetermined set of variable combinations),historic values, iteratively determined (e.g., as described below, suchas regarding S230 and/or S240), and/or otherwise determined. Forexample, each controlled antenna can be controlled to transmit at aspecified phase and/or amplitude (e.g., based on the parameter values,such as with the phase equal to the corresponding phase parameter valueand/or the amplitude equal to the corresponding amplitude parametervalue). However, any other suitable antenna control parameter(s) can bevaried and/or tested.

Measuring results of the transmission S222 preferably includes measuringthe power and/or energy received by one or more receivers. S222 canadditionally or alternatively include measuring reflected and/orbackscattered power (e.g., at the transmitter, at an additional sensor,etc.), and/or measuring any other suitable results of the transmission.S222 can optionally include communicating (e.g., to a coordinatingdevice, such as a transmitter) the measured results and/or any suitableinformation derived based on and/or otherwise associated with themeasured results (e.g., one or more datasets indicative of the measuredresults, such as indicative of the amount of power received by areceiver). In one embodiment, each receiver measures the power that itreceives, and communicates the result of the measurement (and/orinformation determined based on the measurement, such as objectivefunction values, etc.) to the transmitter. The receiver can performmeasurements and/or transmit measurement results continuously, inresponse to requests from the transmitter (e.g., sent by the transmitterbefore, during, and/or in response to performing S221), at regularintervals, and/or with any other suitable timing.

The objective function can be evaluated S223 at the coordinating device,at the measurement device, and/or at any other suitable device. In afirst example (e.g., in which only one receiver is within range of atransmitter), the objective function is a single-variable function(e.g., equal to the received power or power transmission efficiency). Ina second example (e.g., including power transmission to multiplereceivers), the objective function is a multivariable function (e.g., asdescribed above or otherwise). However, S223 can include evaluating anysuitable objective function.

Evaluating candidate values S220 preferably includes caching theevaluated parameter values and the corresponding objective functionvalues (e.g., indexed by the parameter values), and can additionally oralternatively include caching (e.g., indexed by the parameter values)intermediary values (e.g., measured values such as power transmissionand/or reception values; for a multi-receiver system, one or moreindividual-receiver objective function values such as power received bythe receiver; etc.). The values are preferably cached by the transmitter(e.g., in response to receipt of the information from one or morereceivers, in response to calculation of the values, etc.), but canadditionally or alternatively be cached by one or more receivers and/orany other suitable entities. Future iterations of S220 using the sameparameter values preferably include retrieving the correspondingobjective function value from the cache (e.g., rather than performingS221, S222, and/or S223 such as described above, which can require 1-100ms or more). Therefore, caching can significantly reduce the timerequired to evaluate candidate values S220.

In one example, including power transmission to multiple receivers,individual-receiver objective function values (e.g., power received byeach individual receiver) are cached (e.g., along with or in place ofthe overall objective function values and/or any other suitableinformation associated with the parameter values) during S220. In thisexample, the method includes ceasing and/or modifying power transmissionto and/or prioritization of a first set of one or more (but not all) ofthe receivers (e.g., in response to determining that a receiver is nolonger within transmission range, that power delivery to a receiver hasdecreased such as due to movement of the receiver and/or an obstacle,that a receiver charge state is greater than a threshold value, thatanother receiver should be prioritized over this receiver, etc.). Inresponse, the method can include determining a modified transmissionparameter value set (e.g., not optimizing for delivery to receivers ofthe first set, optimizing for the changed reception state of receiversof the first set, etc.), preferably relying on the cached valuesassociated with the one or more receivers not in the first set (e.g.,receivers whose state has not changed significantly). In this example,the cached values associated with the receivers of the first set canoptionally be ignored, discarded, and/or otherwise handled (e.g.,because the values do not correspond to the present physical state ofthe system, and so may not be useful for determining efficienttransmission parameters), but can alternatively be preserved and/or usedin any other suitable manner. In a specific example, optimizedtransmission parameters for delivering power to three receivers aredetermined, and the individual-receiver objective function valuesdetermined during the search for the optimized transmission parametersare cached. In response to the first receiver moving out of effectivecharging range of the transmitter, new transmission parameters fordelivering power to the second and third receivers are determined,preferably based (in part or in full) on the cached values associatedwith the second and third receiver objective functions.

However, S220 can additionally or alternatively include any othersuitable elements performed with any suitable timing.

The candidate values are preferably evaluated S220 during the optimumsearches (e.g., as described below, such as regarding S230 and/or S240).However, they can additionally or alternatively be evaluated S220 at anyother suitable time.

4.2.3 Performing a Local Optimum Search.

Performing a local optimum search S230 can function to quickly determinepotential parameter values (e.g., a locally-optimized parameter valueset, such as an optimal parameter value set near an initial parametervalue set). For example, a local optimum search can be sufficient if thesearch space around the initial transmission parameter values isconvex/quasi-convex, and that convex/quasi-convex region contains asatisfactory objective function value (e.g., the global optimum, a valueabove a minimum threshold or below a maximum threshold, a value within athreshold of a limit such as the global optimum or theoretical limit,etc.). If the local optimum search is sufficient (e.g., finds asatisfactory objective function value), the method can be performed muchfaster than if a global optimum search is employed.

The local optimum search (e.g., maximum search, minimum search) canemploy any suitable local search algorithm(s) (e.g., gradient-basedalgorithm such as gradient descent, conjugate gradient descent, etc.;gradient-free algorithm such as Nelder-Mead, adaptive meshing, etc.),and/or any other suitable algorithms. Performing the local optimumsearch S230 preferably includes repeatedly evaluating candidatetransmission parameter values S220 (e.g., evaluating S220 for each setof candidate transmission parameter values explored by the search).However, S230 can additionally or alternatively include any othersuitable elements, and can be performed in any other suitable manner.

A local search is preferably performed in response to determininginitial parameter values S210 (e.g., beginning the search with theinitial parameter values), and can additionally or alternatively beperformed during a global optimum search (e.g., as described belowregarding S240) and/or at any other suitable times.

4.2.4 Performing a Global Optimum Search.

Performing a global optimum search S240 can potentially function todetermine superior transmission parameter values (e.g., an optimizedparameter value set). The global search is preferably performed S240 inresponse to completion of the initial local search (e.g., beginning thesearch with the optimal parameter values found by the local search), butcan additionally or alternatively be performed in response todetermining initial parameter values S210 (e.g., beginning the searchwith the initial parameter values) and/or at any other suitable time.

A global search is preferably performed S240 only if the global searchis likely to be beneficial. For example, the global search can beperformed if the result of the local search is poor (e.g., the maximumobjective function value found is less than a threshold objectivefunction value), if the global search is expected to yield a significantimprovement over the local search (e.g., based on the pattern ofobjective function values determined during the local search), if thereceiver is expected to remain in range for an extended period of time(e.g., long enough to justify a reduction in charging efficiency duringglobal search performance), and/or based on any other suitable criteria.However, the global search can additionally or alternatively beperformed under any other suitable circumstances (e.g., can be performedin all cases).

The global optimum search (e.g., maximum search, minimum search)preferably employs a stochastic search approach (e.g., particle swarmoptimization, simulated annealing, evolutionary algorithms such asgenetic algorithms, memetic algorithms, dynamic relaxation, ant colonyoptimization, hill climbing with random restarts, stochastic tunneling,tabu search, reactive search optimization, etc.). Especially for thelarge search spaces often encountered in this method, stochastic searchapproaches can typically converge far more quickly than deterministicapproaches. In embodiments including concurrent power transmission tomultiple receivers, the global optimum search can employ amulti-objective search approach (e.g., Pareto Simulated Annealing (PSA),Multi-objective Simulated Annealing (MOSA), Multi-objective GeneticLocal Search (MOGLS), Modified Multi-objective Genetic Local Search(MMOGLS), Non-dominated Sorting Genetic Algorithm (NSGA), StrengthPareto Evolutionary Algorithm (SPEA), etc.). However, the global searchcan additionally or alternatively employ deterministic search approachesand/or any other suitable algorithms.

Initial conditions (e.g., initial particle positions for particle swarmoptimization) for the global search can be predetermined (e.g.,hardcoded), determined randomly, based on (e.g., equal to, randomlydistributed near, etc.) previously-determined transmission parametervalues (e.g., previous optima, results of the most recent local optimumsearch, etc.), can be determined as described above (e.g., regardingS210), and/or can be determined in any other suitable manner. The globalsearch can be terminated after a predetermined amount of iterations orelapsed search time (e.g., fixed amount, amount determined based onfactors such as expected receiver residence time, etc.), after finding asatisfactory objective function value (e.g., as described above, such asregarding the local search), and/or at any other suitable time.

In one embodiment, the global optimum search is performed S240 usingparticle swarm optimization (PSO). PSO can include determining apopulation of particles, each associated with a position in the searchspace (a set of candidate transmission parameter values) and a velocityat which the position is altered (e.g., initially equal for allparticles, such as zero or maximum based on the search space boundaries;randomly determined for each particle; etc.), and then repeatedly (e.g.,at each time step), for each particle of the population: evaluating S220the values associated with the particle, updating the velocity of eachparticle based on a velocity update function, and updating the particleposition based on the updated velocity. The velocity update function fora particle i, which is used at time step t to determine ν_(t+1),preferably depends on the current particle velocity ν_(t,i) and positionx_(t,i), the best position (e.g., position corresponding to the highestor lowest value of the objective function ƒ) that the particle hasvisited p_(i), and the best position that any particle of the populationhas visited g, more preferably tending to drive the particle towardp_(i) and g. For example, the velocity update function can be:v_(t+1,i)=w v_(t,i)+φ_(p) r_(p) (p_(i)−x_(t,i))+φ_(g) r_(g) (g−x_(t,i)),wherein w is an inertial weight, φ_(p) and φ_(g) are parameters (e.g.,constant predetermined parameters), and r_(p) and r_(g) are randomnumbers (e.g., between 0 and 1). The particle position is preferablyupdated by adding the updated velocity to the current particle positionto determine the updated particle position, but can additionally oralternatively be updated in any other suitable manner.

The PSO algorithm preferably includes (e.g., in the update function) oneor more inertial weights, which can function to improve the searchresolution. The inertial weight is preferably determined chaotically(e.g., for iteration-dependent inertial weights w between 0 and 1, thesubsequent inertial weight w_(t+1) can be determined based on thecurrent inertial weight w_(t) by a chaotic relation, such as based onthe equation w_(t+1)=w_(t) (1−w_(t))), but can additionally oralternatively be constant, random, sigmoid increasing, sigmoiddecreasing, linear decreasing, oscillating, global-local best (e.g., forparticle-dependent inertial weights w, the inertial weight w_(i) forparticle i is determined based on the equation

${w_{i} = {a + \frac{g_{best}}{p_{i,{best}}}}},$

wherein p_(i,best) is the best value encountered by particle i, g_(best)is the best value encountered by any particle of the swarm, and a is aconstant such as 1.1), simulated annealing-based (e.g., foriteration-dependent inertial weights w between w_(min) and w_(max),w_(t)=w_(min)+(w_(max)−w_(min))×λ^(t-1), wherein λ, w_(min), and w_(max)are all between 0 and 1), natural exponent, logarithm decreasing,exponent decreasing, adaptively determined, determined based on resultsof an inertial weight optimization algorithm, or any suitablecombination thereof. However, the PSO algorithm can include any othersuitable inertial weight(s). The PSO algorithm preferably includes(e.g., in the update function) one or more fitness-distance-ratio terms(e.g., terms including factors such as

$\frac{{{f\left( x_{i} \right)} - {f\left( x_{j} \right)}}}{{x_{i} - x_{j}}},$

such as

$\max\limits_{j \neq i}\frac{{{f\left( x_{i} \right)} - {f\left( x_{j} \right)}}}{{x_{i} - x_{j}}}$

for j a particle of the population), which can function to reducepremature convergence during the search. The PSO algorithm canadditionally or alternatively include any other suitable features.

Performing the global optimum search S240 preferably includes repeatedlyevaluating candidate transmission parameter values S220 (e.g.,evaluating S220 for each set of candidate transmission parameter valuesexplored by the search). Performing the global search S240 canoptionally include modifying the objective function and/or approximatingobjective function values (e.g., to simplify evaluation and/oraccelerate global search convergence).

In one embodiment, the original objective function ƒ is basined togenerate a modified objective function g, wherein the objective functionvalues are replaced by the minimum value of the basin in which they sit(or analogously, for an objective function to be maximized, the maximumvalue of the hill on which they sit), such as shown in FIG. 3. In thisembodiment, evaluating the modified objective function at a point x(e.g., at a set of candidate transmission parameter values) can includeperforming a local optimum search starting at the point, using theoriginal objective function (e.g., as described above regarding S230),wherein the value of the modified objective function at the point isequal to the value of the original objective function at the localminimum x′: g(x)=ƒ(x′).

A second embodiment includes determining local approximations of theobjective function (e.g., the original objective function ƒ isapproximated to generate a modified objective function g, wherein theobjective function values are replaced by the approximated values). Forexample, the objective function values near a particular point (e.g., aset of candidate transmission parameter values) can be approximatedusing one or more local approximation methods, such as linearregression, quadratic approximation, radial basis functioninterpolation, thin-plate spline interpolation, and/or any othersuitable approximation methods. In a specific example, the objectivefunction value (and/or its derivative(s) with respect to one or moreparameters) is determined at additional locations (in the transmissionparameter space) near the particular point, and these values are used todetermine a local approximation (e.g., interpolated within the region oftested additional locations, extrapolated beyond the region, etc.) ofthe objective function (e.g., wherein the local approximation can betreated as a known objective function value, wherein the localapproximation informs subsequent iterations of the optimum search(es),etc.).

These embodiments preferably includes caching of the modified objectivefunction values (and/or the original objective function values) and thepoints associated with them (e.g., the points evaluated during the localoptimum search and/or local approximation determination, the regionsaround those points, the bounds or known extent of the basin or hill,etc.). In subsequent iterations, the cached values can be retrieved,which may reduce the need to evaluate points via power transmission andmeasurement. The objective function can additionally or alternatively bemodified and/or approximated in any other suitable way (or can remainunmodified). However, S240 can additionally or alternatively include anyother suitable elements, and can be performed in any other suitablemanner.

4.3 Transmitting Power Based on the Transmission Parameter Values.

Transmitting power based on the transmission parameter values S300 canfunction to wirelessly deliver power to the receiver. Power ispreferably transmitted S300 in response to determining the transmissionparameter values S200, but can additionally or alternatively beperformed at any other suitable time. Power is preferably transmittedS300 throughout the receiver's residence time within range of thetransmitter, but can additionally or alternatively be transmittedintermittently, according to a schedule, based on the receiver operationparameters (e.g., state of charge), and/or with any other suitabletiming. The power is preferably transmitted as one or more pure-tone (orsubstantially pure-tone, such as defining a bandwidth less than athreshold bandwidth) signals (e.g., which can be beneficial inembodiments that employ one or more supergaining structures and/or othernarrow bandwidth antennas), but can additionally or alternatively betransmitted in any other suitable form (e.g., in embodiments that employwider-bandwidth antennas, in embodiments in which communication signalsare transmitted along with the power, etc.). In a first specificexample, the radiation has a GHz-scale frequency (e.g., 5-10 GHz, suchas 5.8 GHz and/or greater than 5.8 GHz). In a second specific example,the radiation has a hundreds of MHz-scale frequency (e.g., 100-500 MHz,such as 433 MHz and/or less than 433 MHz). However, the power canadditionally or alternatively be received in any other suitable form.

Transmission parameter value determination S200 (e.g., local searchingS230, global searching S240, etc.) can optionally be repeated duringpower transmission S300 (e.g., wherein power transmission is temporarilyhalted during parameter value determination). Repeated performances ofS200 preferably use the most recently determined transmission parametervalues as initial values, but can additionally or alternatively use anyother suitable values (e.g., as done during the initial performance ofS200, using other previously-determined values, etc.). S200 can berepeated in response to detecting a change (e.g., greater than anabsolute or relative threshold) in delivered power, detecting movement(e.g., based on receiver and/or transmitter measurements, such as IMUmeasurements), detecting an additional receiver and/or transmitter inproximity to the system S100, receiving a user input, can be repeatedperiodically (e.g., at a predetermined rate; at a dynamically-determinedrate, such as determined based on an observed and/or expected temporaland/or spatial stability of the system and/or its performance,preferably wherein lower stability corresponds to a more rapid rate;etc.), sporadically, randomly, and/or can be repeated at any othersuitable time. However, power can be transmitted S300 in any othersuitable manner, and the method can additionally or alternativelyinclude any other suitable elements performed in any other suitablemanner.

An alternative embodiment preferably implements the some or all of abovemethods in a computer-readable medium storing computer-readableinstructions. The instructions are preferably executed bycomputer-executable components preferably integrated with acommunication routing system. The communication routing system mayinclude a communication system, routing system and a pricing system. Thecomputer-readable medium may be stored on any suitable computer readablemedia such as RAMs, ROMs, flash memory, EEPROMs, optical devices (CD orDVD), hard drives, floppy drives, or any suitable device. Thecomputer-executable component is preferably a processor but theinstructions may alternatively or additionally be executed by anysuitable dedicated hardware device.

Although omitted for conciseness, embodiments of the system and/ormethod can include every combination and permutation of the varioussystem components and the various method processes, wherein one or moreinstances of the method and/or processes described herein can beperformed asynchronously (e.g., sequentially), concurrently (e.g., inparallel), or in any other suitable order by and/or using one or moreinstances of the systems, elements, and/or entities described herein.

The FIGURES illustrate the architecture, functionality and operation ofpossible implementations of systems, methods and computer programproducts according to preferred embodiments, example configurations, andvariations thereof. In this regard, each block in the flowchart or blockdiagrams may represent a module, segment, step, or portion of code,which comprises one or more executable instructions for implementing thespecified logical function(s). It should also be noted that, in somealternative implementations, the functions noted in the block can occurout of the order noted in the FIGURES. For example, two blocks shown insuccession may, in fact, be executed substantially concurrently, or theblocks may sometimes be executed in the reverse order, depending uponthe functionality involved. It will also be noted that each block of theblock diagrams and/or flowchart illustration, and combinations of blocksin the block diagrams and/or flowchart illustration, can be implementedby special purpose hardware-based systems that perform the specifiedfunctions or acts, or combinations of special purpose hardware andcomputer instructions.

As a person skilled in the art will recognize from the previous detaileddescription and from the figures and claims, modifications and changescan be made to the preferred embodiments of the invention withoutdeparting from the scope of this invention defined in the followingclaims.

We claim:
 1. A method for wireless power transmission, comprising: at atransmitter comprising an adaptive antenna array, during a timeinterval, transmitting power based on a first parameter value set; at areceiver, during the time interval, receiving power transmitted by thetransmitter; determining an amount of power received at the receiverduring the time interval; determining a second parameter value set basedon the amount of power and the first parameter value set; and at thetransmitter, after the time interval, in response to determining thesecond parameter value set, transmitting power based on the secondparameter value set; wherein the first and second parameter value setsare associated with the adaptive antenna array.
 2. The method of claim1, wherein the transmitter transmits power based on the first parametervalue set substantially throughout the time interval.
 3. The method ofclaim 1, wherein: determining the amount of power is performed at thereceiver; and the method further comprises, before transmitting powerbased on the second parameter value set, at the receiver, sending atransmission indicative of at least one of: the amount of power; and thesecond parameter value set.
 4. The method of claim 3, furthercomprising, at the transmitter, receiving the transmission.
 5. Themethod of claim 4, wherein: the transmission is indicative of the amountof power; and determining the second parameter value set is performed atthe transmitter in response to receiving the transmission.
 6. The methodof claim 3, wherein: during the time interval, the power is transmittedby the transmitter on a first wireless band; and the receiver sends thetransmission on a second wireless band, wherein the first and secondwireless bands are non-overlapping.
 7. The method of claim 1, whereindetermining the second parameter value set is performed according to anoptimization algorithm, comprising, based on the amount of power,determining a value of an objective function associated with theoptimization algorithm.
 8. The method of claim 7, wherein the value isproportional to the amount of power.
 9. The method of claim 7, furthercomprising performing a local search, over a parameter space associatedwith the adaptive antenna array, according to the optimizationalgorithm, wherein: performing the local search comprises determiningthe amount of power and determining the second parameter value set; andthe second parameter value set is associated with an optimum value. 10.The method of claim 7, further comprising performing a stochastic globalsearch, over a parameter space associated with the adaptive antennaarray, according to the optimization algorithm, wherein: performing thestochastic global search comprises determining the amount of power anddetermining the second parameter value set; and the second parametervalue set is associated with an optimum value.
 11. The method of claim10, further comprising, before performing the stochastic global search:performing a local search, over the parameter space, based on theobjective function; based on the local search, determining alocally-optimized parameter value set associated with the transmissionparameter space; and determining that the locally-optimized parametervalue set does not exceed a threshold objective function value, whereinthe stochastic global search is performed in response to determiningthat the locally-optimized parameter value set does not exceed thethreshold objective function value.
 12. The method of claim 1, wherein:the first parameter value set comprises a first amplitude value and afirst phase value; and the second parameter value set comprises a secondamplitude value, different from the first amplitude value, and a secondphase value, different from the first phase value.
 13. The method ofclaim 1, further comprising, before the time interval, at thetransmitter, determining that the receiver is in transmission range ofthe transmitter, wherein transmitting power based on the first parametervalue set is performed in response to determining that the receiver isin transmission range of the transmitter.
 14. A system for wirelesspower transmission, comprising: a power transmitter comprising anadaptive antenna array and a wireless communication receiver, wherein:the power transmitter transmits power based on a first parameter valueset via the adaptive antenna array; the power transmitter receives ametric at the wireless communication receiver; based on the metric andthe first parameter value set, the power transmitter determines a secondparameter value set different from the first parameter value set; andthe power transmitter transmits power based on the second parametervalue set via the adaptive antenna array; and a power receivercomprising a power measurement element and a wireless communicationtransmitter, wherein: the power receiver receives power from the powertransmitter; at the power measurement element, the power receiverdetermines a measurement of the power received; the power receiverdetermines a respective metric based on the measurement; and the powerreceiver transmits the metric to the wireless communication receiver viathe wireless communication transmitter.
 15. The system of claim 14,further comprising a second power receiver, wherein: the second powerreceiver receives power from the power transmitter; the second powerreceiver determines a second measurement of the power received; thesecond power receiver determines a second respective metric based onsecond the measurement; the second power receiver transmits the secondmetric to the wireless communication receiver; and the power transmitterdetermines the second parameter value set based further on the secondmetric.
 16. The system of claim 14, wherein the metric is indicative ofthe measurement.
 17. The system of claim 14, wherein the powertransmitter determines the second parameter value set according to anoptimization algorithm.
 18. The system of claim 17, wherein theoptimization algorithm comprises at least one of: a Nelder-Meadalgorithm, an adaptive meshing algorithm, and a particle swarmoptimization algorithm.
 19. The system of claim 14, wherein the powerreceiver further comprises a supergaining structure.
 20. The system ofclaim 14, wherein: the adaptive antenna array comprises a plurality ofactive antennas; the first parameter value set comprises, for eachactive antenna of the plurality, at least one of: a first respectiveamplitude parameter and a first respective phase parameter; and thesecond parameter value set comprises, for each active antenna of theplurality, at least one of: a second respective amplitude parameter anda second respective phase parameter.